Abstract

Pulse oximetry is a frequently used tool in anesthesia practice. Gives valuable information about arterial oxygen content, tissue perfusion and heart beat rate. In this study we aimed to provide the comparison of peripheral capillary hemoglobin oxygen saturation (SpO2) values among every finger of the two hands. Thirty-seven healthy volunteers from operative room stuffs between the ages of 18–30 years were enrolled in the study. They were monitored after 5 min of rest. After their non invasive blood pressure, heart rate, fasting time and body temperature were measured, SpO2 values were obtained from every finger and each of two hands fingers with the same pulse oximetry. All the SpO2 values were obtained after at least 1 min of measurement period. A total of 370 SpO2 measurements from 37 volunteers were obtained. The highest average SpO2 value was measured from right middle finger (98.2 % ± 1.2) and it was statistically significant when compared with right little finger and left middle finger. The second highest average SpO2 value was measured from right thumb and it was statistically significant only when compared with left middle finger (the finger with the lowest average SpO2 value) (p < 0.05). SpO2 measurement from the fingers of the both hands with the pulse oximetry, the right middle finger and right thumb have statistically significant higher value when compared with left middle finger in right-hand dominant volunteers. We assume that right middle finger and right thumb have the most accurate value that reflects the arterial oxygen saturation.

Keywords

Background

Peripheral capillary oxygen saturation (SpO2) measured by pulse oximeter, is a simple and reliable objective measurement in routine medical practice that approximates the level of oxygen in arterial blood. Measurements with this inexpensive and noninvasive method also provide heart rate and an indication of tissue perfusion (pulse amplitude). Low perfusion (due to hypothermia, low cardiac output, increased systemic vascular resistance, profound anemia or etc.), venous pulsations in a dependent limb, excessive ambient light or motion can cause pulse oximetry artifact. Also, carboxyhemoglobinemia, methemoglobinemia and intravenous dyes can cause false SpO2 readings (Butterworth et al. 2013; Chan et al. 2013; DeMeulenaere 2007). There is no information in the current literature about which finger could give the highest or the reliable recording of SpO2. In this prospective study, we tested in young healthy adults if there is a difference of between-fingers SpO2 values.

Methods

After university ethics committee approval (No: 71306642/050-01-04) and written informed consent was obtained, healthy volunteers from operating room stuff, aging between 18 and 30 years were included in this study in July to August 2013. Volunteers, who were smokers, pregnant or menstruating, having ulnar or radial arterial failure due to Allen test results, having hypotension, bradycardia, anemia or hemoglobinopathy, have nail polish in the fingers, were excluded from the study.

Volunteers with an at least 8 h of fasting period were monitored after 5 min of resting. All SpO2 measurements were done in the same place and ambient light and the same brand monitor (GE B30 Medical system, Freiberg, Germany) was used in all volunteers. All SpO2 values were recorded in the sitting position and simultaneous blood pressure, heart rate and body temperature were noted. Measurements of each finger (abbreviations for fingers used in the text are shown in Table 1) were recorded after waiting at least 1 min.

Table 1

Abbreviations for fingers

Right thumb

R1

Right index finger

R2

Right middle finger

R3

Right ring finger

R4

Right little finger

R5

Left thumb

L1

Left index finger

L2

Left middle finger

L3

Left ring finger

L4

Left little finger

L5

Statistical method

Repeated Anova test was used to compare measurements. If there was significant result a post hoc Bonferroni test was used to evaluate all multiple comparisons (p < 0.05 was considered as statistically significant).

Results

A total of 370 SpO2 measurements obtained from 37 volunteers. Demographic data and hemodynamic results are shown in Table 2. Hypotension, hypothermia, tachycardia, bradycardia did not observed in none of the volunteers. There was no radial or ulnar artery insufficiency determined by Allen test, which was performed clinically. The average SpO2 values of each 10 finger were ranked as follows: R3 > R1 > R2 > R4 > L4 > L1 > L5 > R5 > L2 > L3 and listed in Table 3. Comparison of SpO2 values between fingers is shown in Table 3. Forty-five comparisons were done between fingers (Repeated Anova, F: 3.621, p = 0.004). The highest average SpO2 value was measured from R3 (98.2 % ± 1.2) and it was statistically significant when compared with R5 and L3. The second highest average SpO2 value was measured from R1 and it was statistically significant only when compared with L3 (the finger with the lowest average SpO2 value).

Discussion

According to our results in 35 volunteers with right hand dominance, R3 had the highest average SpO2 value with the pulse oximetry, while in two volunteers with left hand dominance; the L3 had the highest value.

In a survey of health care workers for monitoring pulse oximetry, index finger was selected by 80 % for SpO2 measurement (Mizukoshi et al. 2009). Index finger dominantly is fed from deep palmar arcus created from radial artery. But middle fingers receive both ulnar and radial artery blood supply. Mizukoshi et al. have investigated the most suitable finger for the measurement of the pulse oximetric monitoring. In this study, Perfusion Index (PI) value gave different results in each finger (ANOVA, p < 0.01) and the PI value of the middle finger was measured as the highest both during normoperfusion and hypoperfusion, but no remarkable difference was found in SpO2 values between fingers, which may be due to the insufficient number of subjects (20 volunteers). Also, right or left hand origin or hand-dominance was not documented in that study.

The difference of SpO2 recordings between different fingers may not be clinically important, but this knowledge may be valuable in conditions with poor peripheral perfusion. Dominant hand and higher perfusion may explain the highest value in R3. But, the explanation of the lowest value in L3 is a little complicated. In the non-dominant hand, the size of the finger may become a negative contributing factor that determines the SpO2 recording.

Higher perfusion in the middle finger seems reasonable to expect the highest and most accurate SpO2 value. According to the results of our study, we believe that the middle finger of the dominant hand has the highest and possibly the most accurate SpO2 measurements. The highest SpO2 value can be taken as the most accurate value that reflects the arterial oxygen saturation (SaO2). Because there may be contributing factors that can decrease the SpO2 recording measured by a pulse oximeter lower than SaO2, but there is no contributing factor that can increase the SpO2 recording higher than SaO2 (when a carbon monoxide poisoning like condition does not exist).

The main limitation of our study was the leak of arterial blood gas analysis during SpO2 measurements for determining the accurate value. Another limitation of our study was that, we did not have adequate left hand dominance volunteers. Further studies can be made with adequate number of left hand dominance volunteers or corroborated by arterial blood gas analyses and PI parameters.

In conclusion, SpO2 measurement from the fingers of the both hands with the pulse oximetry, the right middle finger and right thumb have statistically significant higher value when compared with left middle finger in right-hand dominant volunteers. We assume that right middle finger and right thumb have the most accurate value that reflects the arterial oxygen saturation.

Declarations

Authors’ contributions

(1) Conception and design, or acquisition of data, or analysis and interpretation of data; GB, MB, TU. (2) Drafting the manuscript or revising it critically for important intellectual content; ZS, GB, MB, TU. (3) Final approval of the version to be published; KI, UZ, GB, MB, TU. All authors read and approved the final manuscript.

Acknowledgements

The authors appreciate for the contributions of Fumimasa Amaya and Keiko Mizukoshi.

Compliance with ethical guidelines

Competing interests The authors declare that they have no competing interests.

Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Authors’ Affiliations

(1)

Department of Anesthesiology and Reanimation, Bezmialem Vakif University Faculty of Medicine, Istanbul, Turkey